Your search keyword '"M Berriman"' showing total 16 results

1. The mRNA cap methyltransferase gene TbCMT1 is not essential in vitro but is a virulence factor in vivo for bloodstream form Trypanosoma brucei.

Author

Kelner A, Tinti M, Guther MLS, Foth BJ, Chappell L, Berriman M, Cowling VH, and Ferguson MAJ

Subjects

Animals, Female, Gene Deletion, Gene Expression Regulation, Mice, Inbred BALB C, Trypanosoma brucei brucei growth & development, Trypanosomiasis, African pathology, Trypanosomiasis, African veterinary, Virulence, Virulence Factors genetics, Methyltransferases genetics, Protozoan Proteins genetics, RNA Caps genetics, RNA, Protozoan genetics, Trypanosoma brucei brucei genetics, Trypanosoma brucei brucei pathogenicity, Trypanosomiasis, African parasitology

Abstract

Messenger RNA is modified by the addition of a 5' methylated cap structure, which protects the transcript and recruits protein complexes that mediate RNA processing and/or the initiation of translation. Two genes encoding mRNA cap methyltransferases have been identified in T. brucei: TbCMT1 and TbCGM1. Here we analysed the impact of TbCMT1 gene deletion on bloodstream form T. brucei cells. TbCMT1 was dispensable for parasite proliferation in in vitro culture. However, significantly decreased parasitemia was observed in mice inoculated with TbCMT1 null and conditional null cell lines. Using RNA-Seq, we observed that several cysteine peptidase mRNAs were downregulated in TbCMT1 null cells lines. The cysteine peptidase Cathepsin-L was also shown to be reduced at the protein level in TbCMT1 null cell lines. Our data suggest that TbCMT1 is not essential to bloodstream form T. brucei growth in vitro or in vivo but that it contributes significantly to parasite virulence in vivo., Competing Interests: The authors have declared that no competing interests exist.

Published

2018

2. Nitroheterocyclic drug resistance mechanisms in Trypanosoma brucei.

Author

Wyllie S, Foth BJ, Kelner A, Sokolova AY, Berriman M, and Fairlamb AH

Subjects

Genome, Protozoan, Nitroreductases genetics, Nitroreductases metabolism, Parasitic Sensitivity Tests, Polymorphism, Single Nucleotide, Sequence Analysis, DNA, Trypanosoma brucei brucei enzymology, Trypanosoma brucei brucei genetics, Antiprotozoal Agents pharmacology, Drug Resistance, Nifurtimox pharmacology, Nitroimidazoles pharmacology, Trypanosoma brucei brucei drug effects

Abstract

Objectives: The objective of this study was to identify the mechanisms of resistance to nifurtimox and fexinidazole in African trypanosomes., Methods: Bloodstream-form Trypanosoma brucei were selected for resistance to nifurtimox and fexinidazole by stepwise exposure to increasing drug concentrations. Clones were subjected to WGS to identify putative resistance genes. Transgenic parasites modulating expression of genes of interest were generated and drug susceptibility phenotypes determined., Results: Nifurtimox-resistant (NfxR) and fexinidazole-resistant (FxR) parasites shared reciprocal cross-resistance suggestive of a common mechanism of action. Previously, a type I nitroreductase (NTR) has been implicated in nitro drug activation. WGS of resistant clones revealed that NfxR parasites had lost >100 kb from one copy of chromosome 7, rendering them hemizygous for NTR as well as over 30 other genes. FxR parasites retained both copies of NTR, but lost >70 kb downstream of one NTR allele, decreasing NTR transcription by half. A single knockout line of NTR displayed 1.6- and 1.9-fold resistance to nifurtimox and fexinidazole, respectively. Since NfxR and FxR parasites are ∼6- and 20-fold resistant to nifurtimox and fexinidazole, respectively, additional factors must be involved. Overexpression and knockout studies ruled out a role for a putative oxidoreductase (Tb927.7.7410) and a hypothetical gene (Tb927.1.1050), previously identified in a genome-scale RNAi screen., Conclusions: NTR was confirmed as a key resistance determinant, either by loss of one gene copy or loss of gene expression. Further work is required to identify which of the many dozens of SNPs identified in the drug-resistant cell lines contribute to the overall resistance phenotype., (© The Author 2015. Published by Oxford University Press on behalf of the British Society for Antimicrobial Chemotherapy.)

Published

2016

3. Genomic and Proteomic Studies on the Mode of Action of Oxaboroles against the African Trypanosome.

Author

Jones DC, Foth BJ, Urbaniak MD, Patterson S, Ong HB, Berriman M, and Fairlamb AH

Subjects

DNA, Protozoan chemistry, DNA, Protozoan genetics, Drug Resistance, Genome, Protozoan, Genomics, Polymorphism, Genetic, Proteomics, Selection, Genetic, Sequence Analysis, DNA, Antiprotozoal Agents pharmacology, Benzamides pharmacology, Boron Compounds pharmacology, Gene Expression Profiling, Proteome analysis, Trypanosoma brucei brucei drug effects

Abstract

SCYX-7158, an oxaborole, is currently in Phase I clinical trials for the treatment of human African trypanosomiasis. Here we investigate possible modes of action against Trypanosoma brucei using orthogonal chemo-proteomic and genomic approaches. SILAC-based proteomic studies using an oxaborole analogue immobilised onto a resin was used either in competition with a soluble oxaborole or an immobilised inactive control to identify thirteen proteins common to both strategies. Cell-cycle analysis of cells incubated with sub-lethal concentrations of an oxaborole identified a subtle but significant accumulation of G2 and >G2 cells. Given the possibility of compromised DNA fidelity, we investigated long-term exposure of T. brucei to oxaboroles by generating resistant cell lines in vitro. Resistance proved more difficult to generate than for drugs currently used in the field, and in one of our three cell lines was unstable. Whole-genome sequencing of the resistant cell lines revealed single nucleotide polymorphisms in 66 genes and several large-scale genomic aberrations. The absence of a simple consistent mechanism among resistant cell lines and the diverse list of binding partners from the proteomic studies suggest a degree of polypharmacology that should reduce the risk of resistance to this compound class emerging in the field. The combined genetic and chemical biology approaches have provided lists of candidates to be investigated for more detailed information on the mode of action of this promising new drug class.

Published

2015

4. TrypanoCyc: a community-led biochemical pathways database for Trypanosoma brucei.

Author

Shameer S, Logan-Klumpler FJ, Vinson F, Cottret L, Merlet B, Achcar F, Boshart M, Berriman M, Breitling R, Bringaud F, Bütikofer P, Cattanach AM, Bannerman-Chukualim B, Creek DJ, Crouch K, de Koning HP, Denise H, Ebikeme C, Fairlamb AH, Ferguson MA, Ginger ML, Hertz-Fowler C, Kerkhoven EJ, Mäser P, Michels PA, Nayak A, Nes DW, Nolan DP, Olsen C, Silva-Franco F, Smith TK, Taylor MC, Tielens AG, Urbaniak MD, van Hellemond JJ, Vincent IM, Wilkinson SR, Wyllie S, Opperdoes FR, Barrett MP, and Jourdan F

Subjects

Data Mining, Internet, Metabolic Networks and Pathways, Proteomics, Trypanosoma brucei brucei genetics, Databases, Chemical, Trypanosoma brucei brucei metabolism

Abstract

The metabolic network of a cell represents the catabolic and anabolic reactions that interconvert small molecules (metabolites) through the activity of enzymes, transporters and non-catalyzed chemical reactions. Our understanding of individual metabolic networks is increasing as we learn more about the enzymes that are active in particular cells under particular conditions and as technologies advance to allow detailed measurements of the cellular metabolome. Metabolic network databases are of increasing importance in allowing us to contextualise data sets emerging from transcriptomic, proteomic and metabolomic experiments. Here we present a dynamic database, TrypanoCyc (http://www.metexplore.fr/trypanocyc/), which describes the generic and condition-specific metabolic network of Trypanosoma brucei, a parasitic protozoan responsible for human and animal African trypanosomiasis. In addition to enabling navigation through the BioCyc-based TrypanoCyc interface, we have also implemented a network-based representation of the information through MetExplore, yielding a novel environment in which to visualise the metabolism of this important parasite., (© The Author(s) 2014. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2015

5. Antigenic diversity is generated by distinct evolutionary mechanisms in African trypanosome species.

Author

Jackson AP, Berry A, Aslett M, Allison HC, Burton P, Vavrova-Anderson J, Brown R, Browne H, Corton N, Hauser H, Gamble J, Gilderthorp R, Marcello L, McQuillan J, Otto TD, Quail MA, Sanders MJ, van Tonder A, Ginger ML, Field MC, Barry JD, Hertz-Fowler C, and Berriman M

Subjects

Amino Acid Sequence, Animals, Base Sequence, DNA, Protozoan genetics, Humans, Models, Molecular, Molecular Sequence Data, Phylogeny, Protein Conformation, Protozoan Proteins chemistry, Protozoan Proteins genetics, Recombination, Genetic, Sequence Alignment, Sequence Homology, Amino Acid, Species Specificity, Trypanosoma brucei brucei genetics, Trypanosoma congolense genetics, Trypanosoma vivax genetics, Variant Surface Glycoproteins, Trypanosoma chemistry, Variant Surface Glycoproteins, Trypanosoma immunology, Antigenic Variation genetics, Evolution, Molecular, Genome, Protozoan, Immune Evasion genetics, Trypanosoma brucei brucei immunology, Trypanosoma congolense immunology, Trypanosoma vivax immunology, Variant Surface Glycoproteins, Trypanosoma genetics

Abstract

Antigenic variation enables pathogens to avoid the host immune response by continual switching of surface proteins. The protozoan blood parasite Trypanosoma brucei causes human African trypanosomiasis ("sleeping sickness") across sub-Saharan Africa and is a model system for antigenic variation, surviving by periodically replacing a monolayer of variant surface glycoproteins (VSG) that covers its cell surface. We compared the genome of Trypanosoma brucei with two closely related parasites Trypanosoma congolense and Trypanosoma vivax, to reveal how the variant antigen repertoire has evolved and how it might affect contemporary antigenic diversity. We reconstruct VSG diversification showing that Trypanosoma congolense uses variant antigens derived from multiple ancestral VSG lineages, whereas in Trypanosoma brucei VSG have recent origins, and ancestral gene lineages have been repeatedly co-opted to novel functions. These historical differences are reflected in fundamental differences between species in the scale and mechanism of recombination. Using phylogenetic incompatibility as a metric for genetic exchange, we show that the frequency of recombination is comparable between Trypanosoma congolense and Trypanosoma brucei but is much lower in Trypanosoma vivax. Furthermore, in showing that the C-terminal domain of Trypanosoma brucei VSG plays a crucial role in facilitating exchange, we reveal substantial species differences in the mechanism of VSG diversification. Our results demonstrate how past VSG evolution indirectly determines the ability of contemporary parasites to generate novel variant antigens through recombination and suggest that the current model for antigenic variation in Trypanosoma brucei is only one means by which these parasites maintain chronic infections.

Published

2012

6. High-throughput decoding of antitrypanosomal drug efficacy and resistance.

Author

Alsford S, Eckert S, Baker N, Glover L, Sanchez-Flores A, Leung KF, Turner DJ, Field MC, Berriman M, and Horn D

Subjects

Aquaglyceroporins deficiency, Aquaglyceroporins metabolism, Eflornithine pharmacology, Endocytosis drug effects, Glycosylation drug effects, High-Throughput Screening Assays, Humans, Lysosomes drug effects, Lysosomes metabolism, Melarsoprol pharmacology, Nifurtimox pharmacology, Pentamidine pharmacology, RNA Interference, Suramin pharmacology, Trypanocidal Agents therapeutic use, Trypanosoma brucei brucei cytology, Trypanosoma brucei brucei enzymology, Trypanosoma brucei brucei metabolism, Trypanosomiasis, African genetics, Drug Resistance genetics, Trypanocidal Agents pharmacology, Trypanosoma brucei brucei drug effects, Trypanosomiasis, African drug therapy

Abstract

The concept of disease-specific chemotherapy was developed a century ago. Dyes and arsenical compounds that displayed selectivity against trypanosomes were central to this work, and the drugs that emerged remain in use for treating human African trypanosomiasis (HAT). The importance of understanding the mechanisms underlying selective drug action and resistance for the development of improved HAT therapies has been recognized, but these mechanisms have remained largely unknown. Here we use all five current HAT drugs for genome-scale RNA interference target sequencing (RIT-seq) screens in Trypanosoma brucei, revealing the transporters, organelles, enzymes and metabolic pathways that function to facilitate antitrypanosomal drug action. RIT-seq profiling identifies both known drug importers and the only known pro-drug activator, and links more than fifty additional genes to drug action. A bloodstream stage-specific invariant surface glycoprotein (ISG75) family mediates suramin uptake, and the AP1 adaptin complex, lysosomal proteases and major lysosomal transmembrane protein, as well as spermidine and N-acetylglucosamine biosynthesis, all contribute to suramin action. Further screens link ubiquinone availability to nitro-drug action, plasma membrane P-type H(+)-ATPases to pentamidine action, and trypanothione and several putative kinases to melarsoprol action. We also demonstrate a major role for aquaglyceroporins in pentamidine and melarsoprol cross-resistance. These advances in our understanding of mechanisms of antitrypanosomal drug efficacy and resistance will aid the rational design of new therapies and help to combat drug resistance, and provide unprecedented molecular insight into the mode of action of antitrypanosomal drugs.

Published

2012

7. High-throughput phenotyping using parallel sequencing of RNA interference targets in the African trypanosome.

Author

Alsford S, Turner DJ, Obado SO, Sanchez-Flores A, Glover L, Berriman M, Hertz-Fowler C, and Horn D

Subjects

Computational Biology, DNA Primers genetics, Gene Library, Genetic Fitness genetics, Plasmids genetics, Trypanosoma brucei brucei physiology, Genome, Protozoan genetics, Genomics methods, High-Throughput Nucleotide Sequencing methods, Phenotype, RNA Interference, Sequence Analysis, DNA methods, Trypanosoma brucei brucei genetics

Abstract

African trypanosomes are major pathogens of humans and livestock and represent a model for studies of unusual protozoal biology. We describe a high-throughput phenotyping approach termed RNA interference (RNAi) target sequencing, or RIT-seq that, using Illumina sequencing, maps fitness-costs associated with RNAi. We scored the abundance of >90,000 integrated RNAi targets recovered from trypanosome libraries before and after induction of RNAi. Data are presented for 7435 protein coding sequences, >99% of a non-redundant set in the Trypanosoma brucei genome. Analysis of bloodstream and insect life-cycle stages and differentiated libraries revealed genome-scale knockdown profiles of growth and development, linking thousands of previously uncharacterized and "hypothetical" genes to essential functions. Genes underlying prominent features of trypanosome biology are highlighted, including the constitutive emphasis on post-transcriptional gene expression control, the importance of flagellar motility and glycolysis in the bloodstream, and of carboxylic acid metabolism and phosphorylation during differentiation from the bloodstream to the insect stage. The current data set also provides much needed genetic validation to identify new drug targets. RIT-seq represents a versatile new tool for genome-scale functional analyses and for the exploitation of genome sequence data.

Published

2011

8. Trypanosomatid genomes contain several subfamilies of ingi-related retroposons.

Author

Bringaud F, Berriman M, and Hertz-Fowler C

Subjects

Base Sequence, Computational Biology, DNA, Protozoan, Evolution, Molecular, Leishmania major genetics, Molecular Sequence Data, Phylogeny, Genome, Protozoan, Retroelements genetics, Trypanosoma brucei brucei genetics, Trypanosoma cruzi genetics

Abstract

Retroposons are ubiquitous transposable elements found in the genomes of most eukaryotes, including trypanosomatids. The African and American trypanosomes (Trypanosoma brucei and Trypanosoma cruzi) contain long autonomous retroposons of the ingi clade (Tbingi and L1Tc, respectively) and short nonautonomous truncated versions (TbRIME and NARTc, respectively), as well as degenerate ingi-related retroposons devoid of coding capacity (DIREs). In contrast, Leishmania major contains only remnants of extinct retroposons (LmDIREs) and of short nonautonomous heterogeneous elements (LmSIDERs). We extend this comparative and evolutionary analysis of retroposons to the genomes of two other African trypanosomes (Trypanosoma congolense and Trypanosoma vivax) and another Leishmania sp. (Leishmania braziliensis). Three new potentially functional retroposons of the ingi clade have been identified: Tvingi in T. vivax and Tcoingi and L1Tco in T. congolense. T. congolense is the first trypanosomatid containing two classes of potentially active retroposons of the ingi clade. We analyzed sequences located upstream of these new long autonomous ingi-related elements, which code for the recognition site of the retroposon-encoded endonuclease. The closely related Tcoingi and Tvingi elements show the same conserved pattern, indicating that the Tcoingi- and Tvingi-encoded endonucleases share site specificity. Similarly, the conserved pattern previously identified upstream of L1Tc has also been detected at the same relative position upstream of L1Tco elements. A phylogenetic analysis of all ingi-related retroposons identified so far, including DIREs, clearly shows that several distinct subfamilies have emerged and coexisted, though in the course of trypanosomatid evolution, only a few have been maintained as active elements in modern trypanosomatid (sub)species.

Published

2009

9. Telomeric expression sites are highly conserved in Trypanosoma brucei.

Author

Hertz-Fowler C, Figueiredo LM, Quail MA, Becker M, Jackson A, Bason N, Brooks K, Churcher C, Fahkro S, Goodhead I, Heath P, Kartvelishvili M, Mungall K, Harris D, Hauser H, Sanders M, Saunders D, Seeger K, Sharp S, Taylor JE, Walker D, White B, Young R, Cross GA, Rudenko G, Barry JD, Louis EJ, and Berriman M

Subjects

Animals, Antigenic Variation genetics, Cell Line, Chromosome Mapping, Cloning, Molecular, Gene Expression Regulation, Gene Silencing, Host-Parasite Interactions genetics, Phylogeny, Sequence Analysis, DNA, Sequence Tagged Sites, Trypanosoma brucei brucei physiology, Conserved Sequence, Telomere genetics, Transcription Initiation Site physiology, Trypanosoma brucei brucei genetics

Abstract

Subtelomeric regions are often under-represented in genome sequences of eukaryotes. One of the best known examples of the use of telomere proximity for adaptive purposes are the bloodstream expression sites (BESs) of the African trypanosome Trypanosoma brucei. To enhance our understanding of BES structure and function in host adaptation and immune evasion, the BES repertoire from the Lister 427 strain of T. brucei were independently tagged and sequenced. BESs are polymorphic in size and structure but reveal a surprisingly conserved architecture in the context of extensive recombination. Very small BESs do exist and many functioning BESs do not contain the full complement of expression site associated genes (ESAGs). The consequences of duplicated or missing ESAGs, including ESAG9, a newly named ESAG12, and additional variant surface glycoprotein genes (VSGs) were evaluated by functional assays after BESs were tagged with a drug-resistance gene. Phylogenetic analysis of constituent ESAG families suggests that BESs are sequence mosaics and that extensive recombination has shaped the evolution of the BES repertoire. This work opens important perspectives in understanding the molecular mechanisms of antigenic variation, a widely used strategy for immune evasion in pathogens, and telomere biology.

Published

2008

10. The genetic map and comparative analysis with the physical map of Trypanosoma brucei.

Author

MacLeod A, Tweedie A, McLellan S, Taylor S, Hall N, Berriman M, El-Sayed NM, Hope M, Turner CM, and Tait A

Subjects

Animals, Chromosome Mapping, Chromosomes, Genetic Linkage, Physical Chromosome Mapping, Genome, Protozoan, Trypanosoma brucei brucei genetics

Abstract

Trypanosoma brucei is the causative agent of African sleeping sickness in humans and contributes to the debilitating disease 'Nagana' in cattle. To date we know little about the genes that determine drug resistance, host specificity, pathogenesis and virulence in these parasites. The availability of the complete genome sequence and the ability of the parasite to undergo genetic exchange have allowed genetic investigations into this parasite and here we report the first genetic map of T.brucei for the genome reference stock TREU 927, comprising of 182 markers and 11 major linkage groups, that correspond to the 11 previously identified chromosomes. The genetic map provides 90% probability of a marker being 11 cM from any given locus. Its comparison to the available physical map has revealed the average physical size of a recombination unit to be 15.6 Kb/cM. The genetic map coupled with the genome sequence and the ability to undertake crosses presents a new approach to identifying genes relevant to the disease and its prevention in this important pathogen through forward genetic analysis and positional cloning.

Published

2005

11. The genome of the African trypanosome Trypanosoma brucei.

Author

Berriman M, Ghedin E, Hertz-Fowler C, Blandin G, Renauld H, Bartholomeu DC, Lennard NJ, Caler E, Hamlin NE, Haas B, Böhme U, Hannick L, Aslett MA, Shallom J, Marcello L, Hou L, Wickstead B, Alsmark UC, Arrowsmith C, Atkin RJ, Barron AJ, Bringaud F, Brooks K, Carrington M, Cherevach I, Chillingworth TJ, Churcher C, Clark LN, Corton CH, Cronin A, Davies RM, Doggett J, Djikeng A, Feldblyum T, Field MC, Fraser A, Goodhead I, Hance Z, Harper D, Harris BR, Hauser H, Hostetler J, Ivens A, Jagels K, Johnson D, Johnson J, Jones K, Kerhornou AX, Koo H, Larke N, Landfear S, Larkin C, Leech V, Line A, Lord A, Macleod A, Mooney PJ, Moule S, Martin DM, Morgan GW, Mungall K, Norbertczak H, Ormond D, Pai G, Peacock CS, Peterson J, Quail MA, Rabbinowitsch E, Rajandream MA, Reitter C, Salzberg SL, Sanders M, Schobel S, Sharp S, Simmonds M, Simpson AJ, Tallon L, Turner CM, Tait A, Tivey AR, Van Aken S, Walker D, Wanless D, Wang S, White B, White O, Whitehead S, Woodward J, Wortman J, Adams MD, Embley TM, Gull K, Ullu E, Barry JD, Fairlamb AH, Opperdoes F, Barrell BG, Donelson JE, Hall N, Fraser CM, Melville SE, and El-Sayed NM

Subjects

Amino Acids metabolism, Animals, Antigenic Variation, Antigens, Protozoan chemistry, Antigens, Protozoan genetics, Antigens, Protozoan immunology, Carbohydrate Metabolism, Chromosomes genetics, Cytoskeleton chemistry, Cytoskeleton genetics, Cytoskeleton physiology, Ergosterol biosynthesis, Genes, Protozoan, Glutathione metabolism, Glycosylphosphatidylinositols biosynthesis, Humans, Lipid Metabolism, Molecular Sequence Data, Protein Transport, Protozoan Proteins chemistry, Protozoan Proteins metabolism, Pseudogenes, Purines metabolism, Pyrimidines biosynthesis, Recombination, Genetic, Spermidine metabolism, Trypanosoma brucei brucei chemistry, Trypanosoma brucei brucei immunology, Trypanosoma brucei brucei metabolism, Trypanosomiasis, African parasitology, Genome, Protozoan, Glutathione analogs & derivatives, Protozoan Proteins genetics, Sequence Analysis, DNA, Spermidine analogs & derivatives, Trypanosoma brucei brucei genetics

Abstract

African trypanosomes cause human sleeping sickness and livestock trypanosomiasis in sub-Saharan Africa. We present the sequence and analysis of the 11 megabase-sized chromosomes of Trypanosoma brucei. The 26-megabase genome contains 9068 predicted genes, including approximately 900 pseudogenes and approximately 1700 T. brucei-specific genes. Large subtelomeric arrays contain an archive of 806 variant surface glycoprotein (VSG) genes used by the parasite to evade the mammalian immune system. Most VSG genes are pseudogenes, which may be used to generate expressed mosaic genes by ectopic recombination. Comparisons of the cytoskeleton and endocytic trafficking systems with those of humans and other eukaryotic organisms reveal major differences. A comparison of metabolic pathways encoded by the genomes of T. brucei, T. cruzi, and Leishmania major reveals the least overall metabolic capability in T. brucei and the greatest in L. major. Horizontal transfer of genes of bacterial origin has contributed to some of the metabolic differences in these parasites, and a number of novel potential drug targets have been identified.

Published

2005

12. Comparative genomics of trypanosomatid parasitic protozoa.

Author

El-Sayed NM, Myler PJ, Blandin G, Berriman M, Crabtree J, Aggarwal G, Caler E, Renauld H, Worthey EA, Hertz-Fowler C, Ghedin E, Peacock C, Bartholomeu DC, Haas BJ, Tran AN, Wortman JR, Alsmark UC, Angiuoli S, Anupama A, Badger J, Bringaud F, Cadag E, Carlton JM, Cerqueira GC, Creasy T, Delcher AL, Djikeng A, Embley TM, Hauser C, Ivens AC, Kummerfeld SK, Pereira-Leal JB, Nilsson D, Peterson J, Salzberg SL, Shallom J, Silva JC, Sundaram J, Westenberger S, White O, Melville SE, Donelson JE, Andersson B, Stuart KD, and Hall N

Subjects

Animals, Biological Evolution, Chromosomes genetics, Evolution, Molecular, Gene Transfer, Horizontal, Genes, Protozoan, Genomics, Leishmania major chemistry, Leishmania major metabolism, Molecular Sequence Data, Multigene Family, Mutation, Phylogeny, Plastids genetics, Protozoan Proteins chemistry, Protozoan Proteins physiology, Recombination, Genetic, Retroelements, Species Specificity, Symbiosis, Synteny, Telomere genetics, Trypanosoma brucei brucei chemistry, Trypanosoma brucei brucei metabolism, Trypanosoma cruzi chemistry, Trypanosoma cruzi metabolism, Genome, Protozoan, Leishmania major genetics, Proteome, Protozoan Proteins genetics, Trypanosoma brucei brucei genetics, Trypanosoma cruzi genetics

Abstract

A comparison of gene content and genome architecture of Trypanosoma brucei, Trypanosoma cruzi, and Leishmania major, three related pathogens with different life cycles and disease pathology, revealed a conserved core proteome of about 6200 genes in large syntenic polycistronic gene clusters. Many species-specific genes, especially large surface antigen families, occur at nonsyntenic chromosome-internal and subtelomeric regions. Retroelements, structural RNAs, and gene family expansion are often associated with syntenic discontinuities that-along with gene divergence, acquisition and loss, and rearrangement within the syntenic regions-have shaped the genomes of each parasite. Contrary to recent reports, our analyses reveal no evidence that these species are descended from an ancestor that contained a photosynthetic endosymbiont.

Published

2005

13. The ingi and RIME non-LTR retrotransposons are not randomly distributed in the genome of Trypanosoma brucei.

Author

Bringaud F, Biteau N, Zuiderwijk E, Berriman M, El-Sayed NM, Ghedin E, Melville SE, Hall N, and Baltz T

Subjects

Amino Acid Sequence, Animals, Base Sequence, Consensus Sequence, Molecular Sequence Data, Sequence Analysis methods, Genome, Protozoan, Retroelements, Trypanosoma brucei brucei genetics

Abstract

The ingi (long and autonomous) and RIME (short and nonautonomous) non--long-terminal repeat retrotransposons are the most abundant mobile elements characterized to date in the genome of the African trypanosome Trypanosoma brucei. These retrotransposons were thought to be randomly distributed, but a detailed and comprehensive analysis of their genomic distribution had not been performed until now. To address this question, we analyzed the ingi/RIME sequences and flanking sequences from the ongoing T. brucei genome sequencing project (TREU927/4 strain). Among the 81 ingi/RIME elements analyzed, 60% are complete, and 7% of the ingi elements (approximately 15 copies per haploid genome) appear to encode for their own transposition. The size of the direct repeat flanking the ingi/RIME retrotransposons is conserved (i.e., 12-bp), and a strong 11-bp consensus pattern precedes the 5'-direct repeat. The presence of a consensus pattern upstream of the retroelements was confirmed by the analysis of the base occurrence in 294 GSS containing 5'-adjacent ingi/RIME sequences. The conserved sequence is present upstream of ingis and RIMEs, suggesting that ingi-encoded enzymatic activities are used for retrotransposition of RIMEs, which are short nonautonomous retroelements. In conclusion, the ingi and RIME retroelements are not randomly distributed in the genome of T. brucei and are preceded by a conserved sequence, which may be the recognition site of the ingi-encoded endonuclease.

Published

2004

14. The DNA sequence of chromosome I of an African trypanosome: gene content, chromosome organisation, recombination and polymorphism.

Author

Hall N, Berriman M, Lennard NJ, Harris BR, Hertz-Fowler C, Bart-Delabesse EN, Gerrard CS, Atkin RJ, Barron AJ, Bowman S, Bray-Allen SP, Bringaud F, Clark LN, Corton CH, Cronin A, Davies R, Doggett J, Fraser A, Grüter E, Hall S, Harper AD, Kay MP, Leech V, Mayes R, Price C, Quail MA, Rabbinowitsch E, Reitter C, Rutherford K, Sasse J, Sharp S, Shownkeen R, MacLeod A, Taylor S, Tweedie A, Turner CM, Tait A, Gull K, Barrell B, and Melville SE

Subjects

Animals, Chromosome Mapping, DNA, Protozoan chemistry, Microsatellite Repeats genetics, Molecular Sequence Data, Polymorphism, Genetic, Recombination, Genetic, Sequence Analysis, DNA, Variant Surface Glycoproteins, Trypanosoma genetics, Chromosomes genetics, DNA, Protozoan genetics, Genes, Protozoan genetics, Trypanosoma brucei brucei genetics

Abstract

The African trypanosome, Trypanosoma brucei, causes sleeping sickness in humans in sub-Saharan Africa. Here we report the sequence and analysis of the 1.1 Mb chromosome I, which encodes approximately 400 predicted genes organised into directional clusters, of which more than 100 are located in the largest cluster of 250 kb. A 160-kb region consists primarily of three gene families of unknown function, one of which contains a hotspot for retroelement insertion. We also identify five novel gene families. Indeed, almost 20% of predicted genes are members of families. In some cases, tandemly arrayed genes are 99-100% identical, suggesting an active process of amplification and gene conversion. One end of the chromosome consists of a putative bloodstream-form variant surface glycoprotein (VSG) gene expression site that appears truncated and degenerate. The other chromosome end carries VSG and expression site-associated genes and pseudogenes over 50 kb of subtelomeric sequence where, unusually, the telomere-proximal VSG gene is oriented away from the telomere. Our analysis includes the cataloguing of minor genetic variations between the chromosome I homologues and an estimate of crossing-over frequency during genetic exchange. Genetic polymorphisms are exceptionally rare in sequences located within and around the strand-switches between several gene clusters.

Published

2003

15. The architecture of variant surface glycoprotein gene expression sites in Trypanosoma brucei.

Author

Berriman M, Hall N, Sheader K, Bringaud F, Tiwari B, Isobe T, Bowman S, Corton C, Clark L, Cross GA, Hoek M, Zanders T, Berberof M, Borst P, and Rudenko G

Subjects

Animals, Antigenic Variation, Chromosomes, Artificial, Bacterial, DNA, Protozoan analysis, Gene Expression Regulation, Molecular Sequence Data, Sequence Analysis, DNA, Transcription, Genetic, Variant Surface Glycoproteins, Trypanosoma genetics, Telomere genetics, Trypanosoma brucei brucei genetics, Trypanosoma brucei brucei metabolism, Variant Surface Glycoproteins, Trypanosoma chemistry, Variant Surface Glycoproteins, Trypanosoma metabolism

Abstract

Trypanosoma brucei evades the immune system by switching between Variant Surface Glycoprotein (VSG) genes. The active VSG gene is transcribed in one of approximately 20 telomeric expression sites (ESs). It has been postulated that ES polymorphism plays a role in host adaptation. To gain more insight into ES architecture, we have determined the complete sequence of Bacterial Artificial Chromosomes (BACs) containing DNA from three ESs and their flanking regions. There was variation in the order and number of ES-associated genes (ESAGs). ESAGs 6 and 7, encoding transferrin receptor subunits, are the only ESAGs with functional copies in every ES that has been sequenced until now. A BAC clone containing the VO2 ES sequences comprised approximately half of a 330 kb 'intermediate' chromosome. The extensive similarity between this intermediate chromosome and the left telomere of T. brucei 927 chromosome I, suggests that this previously uncharacterised intermediate size class of chromosomes could have arisen from breakage of megabase chromosomes. Unexpected conservation of sequences, including pseudogenes, indicates that the multiple ESs could have arisen through a relatively recent amplification of a single ES.

Published

2002

16. A new, expressed multigene family containing a hot spot for insertion of retroelements is associated with polymorphic subtelomeric regions of Trypanosoma brucei.

Author

Bringaud F, Biteau N, Melville SE, Hez S, El-Sayed NM, Leech V, Berriman M, Hall N, Donelson JE, and Baltz T

Subjects

Amino Acid Sequence, Animals, Base Sequence, Cloning, Molecular, DNA Primers, DNA, Protozoan chemistry, DNA, Protozoan genetics, Escherichia coli genetics, Genes, Protozoan, Molecular Sequence Data, Mutagenesis, Insertional, Phylogeny, Protozoan Proteins chemistry, Protozoan Proteins genetics, Pseudogenes, Sequence Alignment, Sequence Homology, Amino Acid, Telomere genetics, Trypanosoma brucei brucei classification, Trypanosoma cruzi genetics, Multigene Family, Polymorphism, Genetic, Retroelements, Trypanosoma brucei brucei genetics

Abstract

We describe a novel gene family that forms clusters in subtelomeric regions of Trypanosoma brucei chromosomes and partially accounts for the observed clustering of retrotransposons. The ingi and ribosomal inserted mobile element (RIME) non-LTR retrotransposons share 250 bp at both extremities and are the most abundant putatively mobile elements, with about 500 copies per haploid genome. From cDNA clones and subsequently in the T. brucei genomic DNA databases, we identified 52 homologous gene and pseudogene sequences, 16 of which contain a RIME and/or ingi retrotransposon inserted at exactly the same relative position. Here these genes are called the RHS family, for retrotransposon hot spot. Comparison of the protein sequences encoded by RHS genes (21 copies) and pseudogenes (24 copies) revealed a conserved central region containing an ATP/GTP-binding motif and the RIME/ingi insertion site. The RHS proteins share between 13 and 96% identity, and six subfamilies, RHS1 to RHS6, can be defined on the basis of their divergent C-terminal domains. Immunofluorescence and Western blot analyses using RHS subfamily-specific immune sera show that RHS proteins are constitutively expressed and occur mainly in the nucleus. Analysis of Genome Survey Sequence databases indicated that the Trypanosoma brucei diploid genome contains about 280 RHS (pseudo)genes. Among the 52 identified RHS (pseudo)genes, 48 copies are in three RHS clusters located in subtelomeric regions of chromosomes Ia and II and adjacent to the active bloodstream form expression site in T. brucei strain TREU927/4 GUTat10.1. RHS genes comprise the remaining sequence of the size-polymorphic "repetitive region" described for T. brucei chromosome I, and a homologous gene family is present in the Trypanosoma cruzi genome.

Published

2002